CN201852516U - Inlet connector of linear rapid cooling heat exchanger and rapid cooling heat exchanger - Google Patents

Abstract

The utility model provides an inlet connector and a linear rapid cooling heat exchanger adopting the inlet connector. The inlet connector consists of an inlet cone (3), a heat insulation component (4), a seal component (11), a protection sleeve (5) and a cooling medium connector (6). The cooling medium connector (6) is a revolving body with a cross section in the shape of a convex curve surface, and can well absorb the heat expansion differential stress of an inner pipe (7) and an outer pipe (8) of a double-sleeve heat exchange element (2). The protection sleeve (5) performs great heat protection function on a deep hole welding head and the inlet part of the cooling medium connector (6). The inlet connector has simple structure and long service life, and allows cracked gas to dwell in short time. The inlet connector can be used for the linear rapid cooling heat exchanger of a novel ethylene cracking device, and also can be used for modifying the inlet connector of the existing linear rapid cooling heat exchanger.

Description

A kind of linear rapid-cooling heat exchanger inlet connector and rapid-cooling heat exchanger thereof

Technical field

The utility model relates to the equipment that is used for the cracking of ethylene technology, is specifically related to a kind of linear rapid-cooling heat exchanger inlet connector and rapid-cooling heat exchanger thereof.

Background technology

Pyrolysis furnace is the essential elements of ethylene unit.Cracking stock through behind the Pintsch process, enters rapid-cooling heat exchanger and cools off fast in cracking furnace tube, prevents the generation of secondary response, reduces the alkene loss, simultaneously energy recovery is produced steam.Along with the development of ethane cracking furnace chilling technique, in order further to shorten the rapid-cooling heat exchanger adiabatic section time of staying, to avoid cracking gas maldistribution problem, newly-built at present and transformation pyrolysis furnace adopts linear rapid-cooling heat exchanger mostly with rapid-cooling heat exchanger.

As everyone knows, linear rapid-cooling heat exchanger is made up of inlet connector, two sleeve pipe heat exchange element, cooling medium connector, outlet connector, steam header, high-temperature medium header, hydraulic decoking hole etc.Based on this, the version of linear rapid-cooling heat exchanger is as follows: each two sleeve pipe heat exchange element is made up of two concentric pipes, wherein interior pipe is walked the high temperature medium---the cracking gas about 800 ℃, annular space between outer tube and the interior pipe is walked cooling medium---the gas-vapor mix about 350 ℃, each two sleeve pipe heat exchange element is connected with a pyrolysis furnace outlet boiler tube by an inlet connector, two sleeve pipe heat exchange elements are arranged in parallel into single or double arrangement, link together by steam header and high-temperature medium header, form a linear rapid-cooling heat exchanger.The cooling medium connector of prior art adopts oblate tubular construction usually, it can absorb the thermal expansion difference stress between interior pipe of two sleeve pipe heat exchange elements and the outer tube well, but the welding point of pipe and outer tube is a corner joint in the oblate Guan Yushuan sleeve pipe heat exchange element, weld strength is not high, it is bigger to be made factor affecting, particularly oblate pipe and interior limb connect the joint corrosion cracking easily take place, and oblate pipe is connected the Maintenance and Repair inconvenience with the many interior pipes of two sleeve pipe heat exchange elements with outer tube.The cooling medium connector of another kind of prior art adopts double-walled tube sheet connector structure, double-walled tube sheet connector only is connected with one group of two sleeve pipe heat exchange element, and welding point is a banjo fixing butt jointing, but it is big that its shortcoming is a tube plate thickness, thermal expansion difference stress in two sleeve pipe heat exchange elements between pipe and the outer tube will be subdued the manufacture difficulty height by interior pipe prestretched.

Summary of the invention

The purpose of this utility model is to provide a kind of simple in structure, linear rapid-cooling heat exchanger inlet connector of addressing the above problem.

The utility model provides a kind of linear rapid-cooling heat exchanger inlet connector, one end of inlet connector is connected with pyrolysis furnace outlet boiler tube 1, the other end links to each other with two sleeve pipe heat exchange elements 2, it is characterized in that linear rapid-cooling heat exchanger inlet connector mainly is made up of inlet cone 3, protective casing 5, cooling medium connector 6; Inlet cone 3 is the hollow cylinder that a bottom has the tapering transition section, the conical lower portion joint face is a single wall, top cylinder joint face is a double-walled, the single wall joint face of bottom is connected with pyrolysis furnace outlet boiler tube 1, simultaneously along inlet cone 3 length directions, the bottom joint face carries out the transition to the double-walled joint face at top from single wall, is divided into inwall joint face and outer wall joint face, its bottom lock of annular gap between the double-walled joint face at top.The inwall joint face at inlet cone 3 tops is connected with protective casing 5 lower ends, and the outer wall joint face at inlet cone 3 tops is connected with the bottom of cooling medium connector 6.Annular gap between the double-walled joint face at inlet cone 3 tops is built-in with thermal insulation barriers 4, and its bottom contacts with the bottom, annular gap, is equipped with seal 11 between its top and the cooling medium connector 6.Cooling medium connector 6 is that a cross sectional shape is the revolving body of outer convex surface, be divided into top, bottom, front portion, back and two sides, the bottom is connected with the outer wall joint face at inlet cone 3 tops, the top is connected with the outer tube 8 of two sleeve pipe heat exchange elements 2, the front portion is provided with boiler feedwater interface 9, and the back is provided with blowdown cleaning mouth 10.The bottom of cooling medium connector 6 also has stretches boss in one, be connected with the interior pipe 7 of two sleeve pipe heat exchange elements 2, stretch boss and top in the bottom of cooling medium connector 6 and dock the cavity that the welding back forms respectively with interior pipe 7, the outer tube 8 of two sleeve pipe heat exchange elements 2, by the boiler feedwater interface 9 of cooling medium connector 6 front portions, make it to become the coolant guiding channel of introducing.The lower end of protective casing 5 is connected with the inwall joint face at inlet cone 3 tops, and the interior pipe 7 of stretching boss and two sleeve pipe heat exchange elements 2 in the bottom of insertion by cooling medium connector 6, upper end of protective casing 5 is connected in the back cracking gas passage that forms.

Cooling medium connector 6 of the present utility model is that a cross sectional shape is the revolving body of outer convex surface, its structure can absorb between the outer tube 8 of the interior pipe 7 of two sleeve pipe heat exchange elements 2 and two sleeve pipe heat exchange elements 2 well because the different formed swelling heat stress of tube wall temperature, can also reduce the wall thickness of cooling medium connector 6 effectively, make the wall thickness of its wall thickness and two sleeve pipe heat exchange elements 2 on the same order of magnitude, generally between 10mm to 20mm.Stretch boss structure in the bottom of cooling medium connector 6, can make the welding that achieves a butt joint of the interior pipe 7 of cooling medium connector 6 and two sleeve pipe heat exchange elements 2, the butt welded joint forming quality is good, weld strength is high, no obvious stress concentrated, is beneficial to bearing load.

The front portion of cooling medium connector 6 can be provided with boiler feedwater interface 9 to introduce cooling medium in the linear rapid-cooling heat exchanger inlet of the utility model connector, and the bottom at cooling medium connector 6 backs also can be provided with blowdown cleaning mouth 10 to remove impurity in the cooling medium.

The welding point of the linear rapid-cooling heat exchanger inlet of the utility model connector is the butt welding welding point, wherein stretches the docking welding and can adopt deep hole to weld of interior pipe 7 of boss and two sleeve pipe heat exchange elements 2 in cooling medium connector 6 bottoms.

Annular gap in the linear rapid-cooling heat exchanger inlet of the utility model connector between the double-walled joint face at inlet cone 3 tops is built-in with thermal insulation barriers 4, and its bottom contacts with the bottom, annular gap, is equipped with seal 11 between its top and the cooling medium connector 6.

The utility model further proposes; cooling medium connector 6 all can be the solid forging moulding with inlet cone 3; the material of cooling medium connector 6 recommends to select the high chrome molybdenum alloy material; the material of inlet cone 3 and protective casing 5 recommends to select the Langaloy material, and the cone that enters the mouth simultaneously 3 all adopts the nickel-base welding rod welding with the butt weld of cooling medium connector 6 and protective casing 5.

The utility model further proposes, and the insertion depth of protective casing 5 preferably is higher than the deep hole welding point of the interior pipe 7 of stretching boss and two sleeve pipe heat exchange elements 2 in cooling medium connector 6 bottoms, generally between 25mm to 45mm.Good heat protective effect is played in bottom to deep hole welding point and cooling medium connector 6.The outer wall of protective casing 5 is preferably gapped with the inwall of the interior pipe 7 of two sleeve pipe heat exchange elements 2, generally between 1mm to 2mm.

The suggestion of the linear rapid-cooling heat exchanger inlet of the utility model connector adopts the finite element analysis program that numerical analysis is carried out in its temperature field, and reasonably carrying out selection for Machine Design provides foundation.

A kind of linear rapid-cooling heat exchanger chilling inlet connector that adopts the utility model to provide, it is simple in structure, long service life, the cracking gas time of staying is short, cooling medium connector 6 can absorb the interior pipe 7 of two sleeve pipe heat exchange elements 2 and the thermal expansion difference stress between the outer tube 8 well, and is convenient to Maintenance and Repair.Another characteristics are to adopt linear rapid-cooling heat exchanger inlet connector of the present utility model both to can be used for the linear rapid-cooling heat exchanger of newly-built ethylene cracker, are used in the transformation of using as a servant the linear rapid-cooling heat exchanger inlet connector that comes into operation again.

The utility model also provides a kind of rapid-cooling heat exchanger that uses this linearity rapid-cooling heat exchanger inlet connector, mainly forms linear rapid-cooling heat exchanger by inlet connector, two sleeve pipe heat exchange element, cooling medium connector, outlet connector, high-temperature medium fairlead, steam header, high-temperature medium header, hydraulic decoking hole.It is characterized in that more than one inlet connector is arranged in parallel, taking over 14 by the boiler feedwater interface 9 of cooling medium connector 6 front portions with steam is connected, steam adapter 14 is in parallel with steam header 13 again, and two sides of simultaneously adjacent cooling medium connector 6 interconnect.Stretching boss and top in the bottom of cooling medium connector 6 is connected with outer tube 8 with the interior pipe 7 of two sleeve pipe heat exchange elements 2 respectively, the interior pipe 7 of two sleeve pipe heat exchange elements 2 is connected with outer rim with the inner edge of outlet connector 12 respectively with the other end of outer tube 8, the steam (vapor) outlet 15 of outlet connector 12 front portions is taken over 14 with steam and is connected, steam adapter 14 is in parallel with steam header 13 again, and two sides of simultaneously adjacent outlet connector 12 interconnect.High-temperature medium fairlead 18 is connected with outlet connector 12 tops, and high-temperature medium is introduced high-temperature medium header 16, and high-temperature medium header 16 also can be provided with hydraulic decoking hole 17.The cracking gas passage of formation was incorporated in the cooling medium connector 6 after the interior pipe 7 of stretching boss and two sleeve pipe heat exchange elements 2 in the bottom of high-temperature medium by cooling medium connector 6 in the pyrolysis furnace outlet boiler tube 1 was connected, cooling medium is incorporated in the cooling medium connector 6 by the boiler feedwater interface 9 of cooling medium connector 6 front portions, two media begins partition heat exchange in cooling medium connector 6, high-temperature medium enters in the interior pipe 7 of two sleeve pipe heat exchange elements 2 subsequently, cooling medium enters the outer tube 8 of two sleeve pipe heat exchange elements 2 and the annular gap between the interior pipe 7, both continue the partition heat exchange along the length direction of two sleeve pipe heat exchange elements 2, in outlet connector 12.High-temperature medium leads to high-temperature medium header 16 by the high-temperature medium fairlead 18 that links to each other with outlet connector 12 tops, cooling medium is taken over 14 by the steam that links to each other with outlet connector 12 anterior steam (vapor) outlets 15 and is led to steam header 13, and two media finally causes the downstream by high-temperature medium header 16 and steam header 13 respectively.

The utility model further proposes, and the structural shape of cooling medium connector 6 also is applicable to the outlet connector 12 of linear rapid-cooling heat exchanger.Outlet connector 12 is that a cross sectional shape is the revolving body of outer convex surface, be divided into the top, the bottom, anterior, back and two sides, the bottom is connected with the outer tube 8 of two sleeve pipe heat exchange elements 2, the top is connected with high-temperature medium fairlead 18, the front portion is provided with steam (vapor) outlet 15, outlet connector 12 tops also have stretches boss in one, be connected with the interior pipe 7 of two sleeve pipe heat exchange elements 2, stretch in the top of outlet connector 12 boss and bottom respectively with the interior pipe 7 of two sleeve pipe heat exchange elements 2, the cavity that outer tube 8 butt joint welding backs form, steam (vapor) outlet 15 by outlet connector 12 front portions makes it to become the passage that cooling medium is drawn.

The welding point of the linear rapid-cooling heat exchanger outlet of the utility model connector 12 is the butt welding welding point, stretches the docking welding and can adopt deep hole to weld of interior pipe 7 of boss and two sleeve pipe heat exchange elements 2 in the top of its middle outlet connector 12.

The utility model further proposes, and outlet connector 12 can be the solid forging moulding, and the material of outlet connector 12 recommends to select the high chrome molybdenum alloy material.

The utility model further proposes, the pyramidal structure form that the outlet connector also can select prior art to mention.

The rapid-cooling heat exchanger of the linear rapid-cooling heat exchanger inlet of a kind of this use that the utility model provides connector, adopting cross sectional shape is that the cooling medium connector 6 of the revolving body of outer convex surface can absorb between the outer tube 8 of the interior pipe 7 of two sleeve pipe heat exchange elements 2 and two sleeve pipe heat exchange elements 2 well because the different formed swelling heat stress of tube wall temperature, has reduced the wall thickness of cooling medium connector 6 effectively.All welding points are the butt welding welding point, and forming quality is good, weld strength is high, no obvious stress is concentrated, and is beneficial to bearing load.Protective casing 5 also plays good heat protective effect to stretching boss in cooling medium connector 6 bottoms with the deep hole welding point of the interior pipe 7 of two sleeve pipe heat exchange elements 2 and the bottom of cooling medium connector 6 simultaneously.

Description of drawings

Fig. 1 is the longitudinal cross-section structural representation of linear rapid-cooling heat exchanger inlet connector of the present utility model;

Fig. 2 is the longitudinal cross-section structural representation of linear rapid-cooling heat exchanger outlet connector of the present utility model;

Fig. 3 is the longitudinal cross-section structural representation of the linear rapid-cooling heat exchanger conical outlet connector of prior art;

Fig. 4 is the shaft side figure of linear rapid-cooling heat exchanger of the present utility model.

Among the figure: 1--pyrolysis furnace outlet boiler tube, the two sleeve pipe heat exchange elements of 2--, the 3--cone that enters the mouth, 4--thermal insulation barriers; the 5--protective casing, pipe in the 6--cooling medium connector, 7--; the 8--outer tube, 9--boiler feedwater interface, 10--blowdown cleaning mouth; the 11--seal, 12--exports connector, 13--steam header; 14--steam is taken over, 15--vapor interface, 16--high-temperature medium header; 17--hydraulic decoking hole, 18--high-temperature medium fairlead, the conical outlet connector of 19--prior art.

The specific embodiment

Accompanying drawing 1 is to use a kind of linear rapid-cooling heat exchanger inlet connector of the present utility model, only is a kind of form of the present utility model, and the utility model is not limited in this.

Consult Fig. 1, an end of inlet connector docks welding with pyrolysis furnace outlet boiler tube 1, and the other end docks welding with two sleeve pipe heat exchange elements 2.Pintsch process gas enters linear rapid-cooling heat exchanger from pyrolysis furnace outlet boiler tube 1.

Consult Fig. 1, the inlet connector is made up of inlet cone 3, thermal insulation barriers 4, seal 11, protective casing 5 and cooling medium connector 6.The bottom of cooling medium connector 6 also has stretches boss in one, be connected with the interior pipe 7 of two sleeve pipe heat exchange elements 2, stretch boss and top in the bottom of cooling medium connector 6 and dock the cavity that the welding back forms respectively with interior pipe 7, the outer tube 8 of two sleeve pipe heat exchange elements 2, become the flow channel of cooling medium.Cooling medium connector 6 is that a cross sectional shape is the revolving body of outer convex surface, and preferably cross sectional shape is oval revolving body.Find after deliberation, cross sectional shape can absorb for oval rotary structure between the outer tube 8 of the interior pipe 7 of two sleeve pipe heat exchange elements 2 and two sleeve pipe heat exchange elements 2 well because the different formed swelling heat stress of tube wall temperature, can also reduce the wall thickness of cooling medium connector 6 effectively, make the wall thickness of its wall thickness and two sleeve pipe heat exchange elements 2 on the same order of magnitude, generally between 10mm to 20mm.

Cooling medium connector 6 front portions are provided with boiler feedwater interface 9 to introduce cooling medium, and cooling medium stretches boss in the bottom of cooling medium connector 6 and the top is docked in the cavity that forms after the welding mobile respectively with interior pipe 7, the outer tube 8 of two sleeve pipe heat exchange elements 2.The bottom, back of cooling medium connector 6 also is provided with blowdown cleaning mouth 10, can play the blowdown effect that is interrupted on the one hand, during online on the other hand impatient cold heat exchanger parking maintenance, available corresponding tool carries out mechanical removal by blowdown cleaning mouthful 10 impurity that will be deposited on cooling medium connector 6 inner bottom.

As shown in Figure 1; inlet cone 3 bottom joint faces and pyrolysis furnace outlet boiler tube 1, inlet cone 3 top inner wall joint faces are the butt welding welding point with protective casing 5 lower ends, inlet cone 3 top exterior walls joint faces with the welding point of cooling medium connector 6 bottoms, cone that enters the mouth 3 and protective casing 5, the formation of cooling medium connector 6 postweldings annular space in thermal insulation barriers 4, seal 11 are housed.Cooling medium connector 6 also is the butt welding welding point with the welding point of two sleeve pipe heat exchange elements 2, wherein stretches boss in the bottom of cooling medium connector 6 and adopts the deep hole weldering with the welding of docking of the interior pipe 7 of two sleeve pipe heat exchange elements 2.

The outer wall of assembling back protective casing 5 is 1mm with the inwall gap of the interior pipe 7 of two sleeve pipe heat exchange elements 2, and protective casing 5 can be along its axial free wxpansion; The insertion depth of protective casing 5 is higher than the deep hole welding point 30mm that stretches boss and the interior pipe 7 of two sleeve pipe heat exchange elements 2 in the bottom of cooling medium connector 6, and deep hole welding point and cooling medium connector 6 bottoms are played good heat protective effect.

As shown in Figure 1, cooling medium connector 6 is the solid forging moulding with inlet cone 3, the material selection high chrome molybdenum alloy material of cooling medium connector 6, the material selection Langaloy material of inlet cone 3 and protective casing 5.Inlet cone 3 all adopts the nickel-base welding rod welding with the butt welded joint of cooling medium connector 6 and protective casing 5.

Consult Fig. 2, outlet connector 12 also is that a cross sectional shape is the revolving body of outer convex surface, and preferably cross sectional shape is oval revolving body.Outlet connector 12 tops also have stretches boss in one, be connected with the interior pipe 7 of two sleeve pipe heat exchange elements 2, stretch boss and bottom in the top of outlet connector 12 and dock the cavity that the welding back forms respectively with interior pipe 7, the outer tube 8 of two sleeve pipe heat exchange elements 2, become the passage that cooling medium is drawn by the steam (vapor) outlet 15 that exports connector 12 front portions.Outlet connector 12 is the solid forging moulding, the material selection high chrome molybdenum alloy material of outlet connector 12.Outlet connector 12 also is the butt welding welding point with the welding point of two sleeve pipe heat exchange elements 2, stretches the docking welding and can adopt deep hole to weld of interior pipe 7 of boss and two sleeve pipe heat exchange elements 2 in the top of its middle outlet connector 12.The wall thickness of outlet connector 12 and the wall thickness of two sleeve pipe heat exchange elements 2 are on the same order of magnitude, generally between 10mm to 20mm.

Consult Fig. 3, the pyramidal structure form that the outlet connector also can select prior art to mention, the outlet connector 19 of prior art is one to have the hollow cylinder of tapering transition section, the conical top joint face is a single wall, the bottom joint face is a double-walled, the single wall joint face at top is connected with high-temperature medium fairlead 18, simultaneously along outlet connector 19 length directions, the top joint face carries out the transition to the double-walled joint face of bottom from single wall, be divided into inwall joint face and outer wall joint face, its top seal of annular gap between the double-walled joint face of bottom.The inwall joint face of outlet connector 19 bottoms is connected with the interior pipe 7 of two sleeve pipe heat exchange elements 2, and the outer wall joint face of bottom is connected with the outer tube 8 of two sleeve pipe heat exchange elements 2.

Consult Fig. 4, the inlet connector is arranged in parallel, and the boiler feedwater interface 9 by cooling medium connector 6 front portions is taken over 14 with steam and is connected, and steam adapter 14 is in parallel with steam header 13 again, and two sides of the cooling medium connector 6 that the while is adjacent interconnect.Stretching boss and top in the bottom of cooling medium connector 6 is connected with outer tube 8 with the interior pipe 7 of two sleeve pipe heat exchange elements 2 respectively, the interior pipe 7 of two sleeve pipe heat exchange elements 2 and the other end of outer tube 8 are stretched boss and are connected with the bottom respectively with in outlet connector 12 tops, the steam (vapor) outlet 15 of outlet connector 12 front portions is taken over 14 with steam and is connected, steam adapter 14 is in parallel with steam header 13 again, and two sides of simultaneously adjacent outlet connector 12 interconnect.High-temperature medium fairlead 18 is connected with outlet connector 12 tops, and high-temperature medium is introduced high-temperature medium header 16, and high-temperature medium header 16 also can be provided with hydraulic decoking hole 17.Linear rapid-cooling heat exchanger is formed in inlet connector, two sleeve pipe heat exchange element, cooling medium connector, outlet connector, high-temperature medium fairlead, steam header, high-temperature medium header, hydraulic decoking hole.

Claims (19)

1. linear rapid-cooling heat exchanger inlet connector, one end of inlet connector is connected with pyrolysis furnace outlet boiler tube (1), the other end links to each other with two sleeve pipe heat exchange elements (2), it is characterized in that linear rapid-cooling heat exchanger inlet connector mainly is made up of the cone (3) that enters the mouth, thermal insulation barriers (4), seal (11), protective casing (5), cooling medium connector (6); Inlet cone (3) is one to have the hollow cylinder of tapering transition section, the conical lower portion joint face is a single wall, the top joint face is a double-walled, the single wall joint face of bottom is connected with pyrolysis furnace outlet boiler tube (1), simultaneously along inlet cone (3) length direction, the bottom joint face carries out the transition to the double-walled joint face at top from single wall, is divided into inwall joint face and outer wall joint face, its bottom lock of annular gap between the double-walled joint face at top; The inwall joint face at inlet cone (3) top is connected with protective casing (5) lower end, and the outer wall joint face at inlet cone (3) top is connected with the bottom of cooling medium connector (6); Annular gap between the double-walled joint face at inlet cone (3) top is built-in with thermal insulation barriers (4), and its bottom contacts with the bottom, annular gap, is equipped with seal (11) between its top and the cooling medium connector (6); Cooling medium connector (6) is that a cross sectional shape is the revolving body of outer convex surface, be divided into top, bottom, front portion, back and two sides, the bottom is connected with the outer wall joint face at inlet cone (3) top, the top is connected with the outer tube (8) of two sleeve pipe heat exchange elements (2), the front portion is provided with boiler feedwater interface (9), and the back is provided with blowdown cleaning mouthful (10); The bottom of cooling medium connector (6) also has stretches boss in one, be connected with the interior pipe (7) of two sleeve pipe heat exchange elements (2), stretch boss and top in the bottom of cooling medium connector (6) and dock the cavity that the welding back forms respectively with interior pipe (7), the outer tube (8) of two sleeve pipe heat exchange elements (2), by the anterior boiler feedwater interface (9) of cooling medium connector (6), make it to become the coolant guiding channel of introducing; The lower end of protective casing (5) is connected with the inwall joint face at inlet cone (3) top, and the interior pipe (7) of stretching boss and two sleeve pipe heat exchange elements (2) in the bottom of insertion by cooling medium connector (6), upper end of protective casing (5) is connected in the back cracking gas passage that forms.

2. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that cooling medium connector (6) is that a cross sectional shape is oval revolving body.

3. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that the welding point of linear rapid-cooling heat exchanger inlet connector is the butt welding welding point.

4. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that the wall thickness of cooling medium connector (6) and the wall thickness of two sleeve pipe heat exchange elements (2) are 10mm～20mm.

5. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that stretching in cooling medium connector (6) bottom boss and adopts the deep hole weldering with the welding of docking of the interior pipe (7) of two sleeve pipe heat exchange elements (2).

6. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that cooling medium connector (6) and inlet cone (3) are the solid forging moulding.

7. linear rapid-cooling heat exchanger inlet connector according to claim 1, the material that it is characterized in that cooling medium connector (6) is the high chrome molybdenum alloy material, the material of inlet cone (3) and protective casing (5) is the Langaloy material.

8. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that the cooling medium connector (6) and the butt welded joint of inlet cone (3) and inlet cone (3) and protective casing (5) all adopt the nickel-base welding rod welding.

9. linear rapid-cooling heat exchanger inlet connector according to claim 1 is characterized in that the insertion depth of protective casing (5) is higher than the deep hole welding point of stretching the interior pipe (7) of boss and two sleeve pipe heat exchange elements (2) in cooling medium connector (6) bottom; The outer wall of protective casing (5) is gapped with the inwall of the interior pipe (7) of two sleeve pipe heat exchange elements (2).

10. linear rapid-cooling heat exchanger inlet connector according to claim 9 is characterized in that the insertion depth of protective casing (5) exceeds the deep hole welding point 25mm～45mm that stretches the interior pipe (7) of boss and two sleeve pipe heat exchange elements (2) in cooling medium connector (6) bottom.

11. linear rapid-cooling heat exchanger inlet connector according to claim 9, the outer wall that it is characterized in that protective casing (5) is 1mm～2mm with the gap of the inwall of the interior pipe (7) of two sleeve pipe heat exchange elements (2).

12. linear rapid-cooling heat exchanger that contains the described inlet connector of claim 1, mainly by the inlet connector, two sleeve pipe heat exchange elements, the cooling medium connector, the outlet connector, the high-temperature medium fairlead, the steam header, the high-temperature medium header, the hydraulic decoking hole is formed, it is characterized in that more than one inlet connector is arranged in parallel, taking over (14) by the anterior boiler feedwater interface (9) of cooling medium connector (6) with steam is connected, it is in parallel with steam header (13) again that steam is taken over (14), and two sides of simultaneously adjacent cooling medium connector (6) interconnect; Stretching boss and top in the bottom of cooling medium connector (6) is connected with outer tube (8) with the interior pipe (7) of two sleeve pipe heat exchange elements (2) respectively, the interior pipe (7) of two sleeve pipe heat exchange elements (2) is connected with outer rim with the inner edge of outlet connector (12) respectively with the other end of outer tube (8), the anterior steam (vapor) outlet (15) of outlet connector (12) is taken over (14) with steam and is connected, it is in parallel with steam header (13) again that steam is taken over (14), and two sides of simultaneously adjacent outlet connector (12) interconnect; High-temperature medium fairlead (18) is connected with outlet connector (12) top, and high-temperature medium is introduced high-temperature medium header (16).

13. linear rapid-cooling heat exchanger according to claim 12, it is characterized in that exporting connector (12) is that a cross sectional shape is the revolving body of outer convex surface, be divided into the top, the bottom, anterior, back and two sides, the bottom is connected with the outer tube (8) of two sleeve pipe heat exchange elements (2), the top is connected with high-temperature medium fairlead (18), the front portion is provided with steam (vapor) outlet (15), outlet connector (12) top has stretches boss in one, be connected with the interior pipe (7) of two sleeve pipe heat exchange elements (2), stretch in the top of outlet connector (12) boss and bottom respectively with the interior pipe (7) of two sleeve pipe heat exchange elements (2), the cavity that outer tube (8) butt joint welding back forms, by the anterior steam (vapor) outlet (15) of outlet connector (12), make it to become the passage that cooling medium is drawn.

14. linear rapid-cooling heat exchanger according to claim 12, it is characterized in that exporting connector (12) is that cross sectional shape is oval revolving body.

15. linear rapid-cooling heat exchanger according to claim 12 is characterized in that the welding point that exports connector (12) is the butt welding welding point.

16. linear rapid-cooling heat exchanger according to claim 12 is characterized in that exporting the wall thickness of connector (12) and the wall thickness of two sleeve pipe heat exchange elements (2) is 10mm～20mm.

17. linear rapid-cooling heat exchanger according to claim 12 is characterized in that exporting and stretches boss in connector (12) top and adopt the deep hole weldering with the welding of docking of the interior pipe (7) of two sleeve pipe heat exchange elements (2).

18. linear rapid-cooling heat exchanger according to claim 12 is characterized in that exporting connector (12) and is the solid forging moulding.

19. linear rapid-cooling heat exchanger according to claim 12 is characterized in that exporting connector (12), material is the high chrome molybdenum alloy material.

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